In many real-world networks, the rates of node and link addition are time dependent. This observation motivates the definition of accelerating networks. There has been relatively little investigation of accelerating networks and previous efforts at analyzing their degree distributions have employed mean-field techniques. By contrast, we show that it is possible to apply a master-equation approach to such network development. We provide full time-dependent expressions for the evolution of the degree distributions for the canonical situations of random and preferential attachment in networks undergoing constant acceleration. These results are in excellent agreement with results obtained from simulations. We note that a growing nonequilibrium ...
A key ingredient of many current models proposed to capture the topological evolution of complex net...
We present a continuum formalism for modeling growing random networks under addition and deletion of...
The traditional way of studying temporal networks is to aggregate the dynamics of the edges to creat...
In many real-world networks, the rates of node and link addition are time dependent. This observatio...
Networks are commonly observed structures in complex systems with interacting and interdependent pa...
Preferential attachment drives the evolution of many complex networks. Its analytical studies mostly...
We present a simple model of network growth and solve it by writing the dynamic equations for its ma...
Our work introduces an approach for estimating the contribution of attachment mechanisms to the for...
Prediction and control of network dynamics are grand-challenge problems in network science. The lack...
We propose a mathematical description of a dynamic network model in which the number of links fluctu...
We obtain closed form expressions for the expected conditional degree distribution and the joint deg...
We study a simple model of dynamic networks, characterized by a set preferred degree, κ. Each node w...
AbstractWe study a simple model involving adaptive networks in which the nodes add or cut links to o...
The study of networks is in great focus of many branches of sci-ence. We suggest a novel approach to...
We show that to explain the growth of the citation network by preferential attachment (PA), one has ...
A key ingredient of many current models proposed to capture the topological evolution of complex net...
We present a continuum formalism for modeling growing random networks under addition and deletion of...
The traditional way of studying temporal networks is to aggregate the dynamics of the edges to creat...
In many real-world networks, the rates of node and link addition are time dependent. This observatio...
Networks are commonly observed structures in complex systems with interacting and interdependent pa...
Preferential attachment drives the evolution of many complex networks. Its analytical studies mostly...
We present a simple model of network growth and solve it by writing the dynamic equations for its ma...
Our work introduces an approach for estimating the contribution of attachment mechanisms to the for...
Prediction and control of network dynamics are grand-challenge problems in network science. The lack...
We propose a mathematical description of a dynamic network model in which the number of links fluctu...
We obtain closed form expressions for the expected conditional degree distribution and the joint deg...
We study a simple model of dynamic networks, characterized by a set preferred degree, κ. Each node w...
AbstractWe study a simple model involving adaptive networks in which the nodes add or cut links to o...
The study of networks is in great focus of many branches of sci-ence. We suggest a novel approach to...
We show that to explain the growth of the citation network by preferential attachment (PA), one has ...
A key ingredient of many current models proposed to capture the topological evolution of complex net...
We present a continuum formalism for modeling growing random networks under addition and deletion of...
The traditional way of studying temporal networks is to aggregate the dynamics of the edges to creat...